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EVALUATION OF ULTRAVIOLET (UV)
RADIATION DISINFECTION
TECHNOLOGIES FOR WASTEWATER
TREATMENT PLANT EFFLUENT
FINAL REPORT 04 -07
DECEMBER 2004
NEW YORK STATE ENERGY RESEARCH AND
DEVELOPMENT AUTHORITY
The New York State Energy Research and Development Authority (NYSERDA) is a public benefit
corporation created in 1975 by the New York State Legislature. NYSERDA’s responsibilities include:
• Conducting a multifaceted energy and environmental research and development program to meet
New York State’s diverse economic needs.
• Administering the New York Energy $martSM program, a Statewide public benefit R&D, energy
efficiency, and environmental protection program.
• Making energy more affordable for residential and low-income households.
• Helping industries, schools, hospitals, municipalities, not-for-profits, and the residential sector,
including low-income residents, implement energy-efficiency measures.
• Providing objective, credible, and useful energy analysis and planning to guide decisions made by
major energy stakeholders in the private and public sectors.
• Managing the Western New York Nuclear Service Center at West Valley, including: (1) overseeing the
State’s interests and share of costs at the West Valley Demonstration Project, a federal/State radioac
tive waste clean-up effort, and (2) managing wastes and maintaining facilities at the shut-down State-
Licensed Disposal Area.
• Coordinating the State’s activities on energy emergencies and nuclear regulatory matters, and
monitoring low-level radioactive waste generation and management in the State.
• Financing energy-related projects, reducing costs for ratepayers.
NYSERDA administers the New York Energy $martSM program, which is designed to support certain
public benefit programs during the transition to a more competitive electricity market. Some 2,700
projects in 40 programs are funded by a charge on the electricity transmitted and distributed by the State’s
investor-owned utilities. The New York Energy $martSM program provides energy efficiency services,
including those directed at the low-income sector, research and development, and environmental protec
tion activities.
NYSERDA derives its basic research revenues from an assessment on the intrastate sales of New York
State’s investor-owned electric and gas utilities, and voluntary annual contributions by the New York
Power Authority and the Long Island Power Authority. Additional research dollars come from limited
corporate funds. Some 400 NYSERDA research projects help the State’s businesses and municipalities
with their energy and environmental problems. Since 1990, NYSERDA has successfully developed and
brought into use more than 150 innovative, energy-efficient, and environmentally beneficial products,
processes, and services. These contributions to the State’s economic growth and environmental protection
are made at a cost of about $.70 per New York resident per year.
Federally funded, the Energy Efficiency Services program is working with more than 540 businesses,
schools, and municipalities to identify existing technologies and equipment to reduce their energy costs.
For more information, contact the Communications unit, NYSERDA, 17 Columbia Circle, Albany,
New York 12203-6399; toll-free 1-866-NYSERDA, locally (518) 862-1090, ext. 3250; or on the web
at www.nyserda.org
STATE OF NEW YORK ENERGY RESEARCH AND DEVELOPMENT AUTHORITY
George E. Pataki Vincent A. DeIorio, Esq., Chairman
Governor Peter R. Smith, President
http:www.nyserda.org
EVALUATION OF
ULTRAVIOLET (UV) RADIATION
DISINFECTION TECHNOLOGIES FOR
WASTEWATER TREATMENT PLANT EFFLUENT
FINAL REPORT
Prepared for the
NEW YORK STATE
ENERGY RESEARCH AND
DEVELOPMENT AUTHORITY Albany, NY
www.nyserda.org
Kathleen O’Connor
Project Manager
NATIONAL GRID CORPORATION Syracuse, NY
and
ERIE COUNTY DEPARTMENT OF ENVIRONMENT AND
PLANNING SOUTHTOWNS SEWAGE AGENCY Buffalo, NY
Prepared by
URS CORPORATION Buffalo, NY
Christopher P. Martin, P.E.,
Project Manager
with
STAN TEC, INC Guelph, ON
Keith Holtz
and
UNIVERSITY AT BUFFALO James N. Jensen, PH.D.
Associate Professor
NYSERDA NYSERDA 4818 December 2004
Report 04-07
http:www.nyserda.org
NOTICE
This report was prepared by URS Corporation (URS), the University at Buffalo (UB) and StanTec, Inc.
(STANTEC) in the course of performing work contracted for and sponsored by the New York State Energy
Research and Development Authority, National Grid Corporation and the Erie County Department of
Environment and Planning, New York (hereafter the “Sponsors”). The opinions expressed in this report do
not necessarily reflect those of the Sponsors or the State of New York, and reference to any specific
product, service, process, or method does not constitute an implied or expressed recommendation or
endorsement of it. Further, the Sponsors and the State of New York make no warranties or representations,
expressed or implied, as to the fitness for particular purpose or implied, as to the fitness for particular
purpose or merchantability of any product, apparatus, or service, or the usefulness, completeness, or
accuracy of any processes, methods, or other information contained, described, disclosed, or referred to in
this report. The Sponsors, the State of New York, and the contractors make no representation that the use
of any product, apparatus, process, method, or other information will not infringe privately owned rights
and will assume no liability for any loss, injury, or damage resulting from, or occurring in connection with,
the use of information contained, described, disclosed, or referred to in this report.
ABSTRACT
To evaluate the costs and benefits of using UV instead of chlorine for disinfection of wastewater treatment plant
(WWTP) effluent, the New York State Energy Research and Development Authority, National Grid and the Erie
County Department of Environment and Planning sponsored a pilot-scale demonstration at the Erie County
Southtowns WWTP. The demonstration included three pilot-scale units for the evaluation of three different UV
lamp types: low-pressure/low-intensity (lp-li), low-pressure/high-intensity (lp-hi), and medium-pressure/high
intensity (mp-hi). The demonstration was performed jointly by URS Corporation, the State University of New
York at Buffalo and StanTec, Inc.
Four aspects of UV disinfection were evaluated with the three pilot units: operational requirements, disinfection
efficiency for fecal coliforms, water quality assessment of the influent, and toxicity tests with rainbow trout and
Daphnia magna on chlorinated and UV-treated wastewaters.
The primary conclusions of the study are as follows. First, the primary operation and maintenance requirement
in UV disinfection is lamp cleaning. In this study, lamp cleaning was successful in restoring the measured UV
intensity. Second, total iron and TSS appeared to be correlated (perhaps because the plant influent TSS appeared
to have a constant iron content or because dosing of ferric salts for phosphate control may be tied to TSS in the
plant influent). Third, all three systems exhibited tailing at log kills greater than about 2. Higher log kills (2.7 –
2.9) are required to achieve an effluent of 200 MPN/100 mL. The recommended doses to achieve 2.7 – 2.9 log
kills are 3, 4.5, and 8 mW-s/cm2 for the lp-li, lp-hi, and mp-hi units, respectively. Fourth, no acute toxicity to
Daphnia magna was seen in any of the UV treated streams during the same period. For rainbow trout tests, all
UV treated effluents had at least one toxic event during the sampling period. Two samples from the low
pressure/high intensity treated stream were toxic to rainbow trout. When compared to chlorine treatment, UV
treatment significantly reduces whole effluent toxicity to rainbow trout and Daphnia.
ACKNOWLEDGEMENTS
We dedicate this report to the memory of Martin O’Reilly, who was essential in completing the effluent
toxicity testing for this project.
We wish to acknowledge the contributions of the following people who were instrumental and greatly
appreciated in the completion of this project:
ECDEP: Gerald L. Devlin, P.E.
Glenn Absolom
Mark Fitzgerald
James Keller
Southtowns WWTP Employees
URS: Lori Lehnen, P.E.
Rebecca Wightman
UB: Bethany Madge, Ph.D.
StanTec: Martin O’Reilly
This project could not have been completed without the patience and persistence of all people involved.
TABLE OF CONTENTS
Section Page
NOTICE
ABSTRACT ....................................................................................................................................... iii
ACKNOWLEDGEMENTS................................................................................................................ iv
SUMMARY ....................................................................................................................................... S-1
1 INTRODUCTION ............................................................................................................... 1-1
2 BACKGROUND ............................................................................................................... 2-1
CHLORINE AND UV DISINFECTION............................................................................. 2-1 Chlorine Disinfection Issues ................................................................................................ 2-1 Ultraviolet (UV) Radiation Disinfection.............................................................................. 2-1
ALTERNATIVE UV DISINFECTION TECHNOLOGIES................................................ 2-3
FACTORS THAT IMPACT UV DISINFECTION ............................................................. 2-4 Disinfection Efficacy ........................................................................................................... 2-4 UV Transmittance, Suspended Solids and Particle Shading ................................................ 2-6 UV Reactor Hydraulics and Configuration .......................................................................... 2-8 Lamp Fouling ................................................................................................................. 2-9 Environmental Factors ......................................................................................................... 2-11 Photoreactivation and Nucleotide Excision Repair .............................................................. 2-11 Safety Concerns with Using UV .......................................................................................... 2-13
3 PROJECT OBJECTIVES .................................................................................................... 3-1
4 EXISTING SOUTHTOWNS WWTP FACILITIES AND EFFLUENT WATER QUALITY 4-1
5 PILOT PLANT DESIGN ................................................................................................... 5-1
6 DATA COLLECTION METHODS .................................................................................... 6-1
SAMPLE COLLECTION ................................................................................................... 6-1
MICROBIAL ANALYSIS METHODS .............................................................................. 6-1
OTHER WATER QUALITY ANALYSIS METHODS...................................................... 6-2
EXPERIMENTAL APPROACHES FOR DISINFECTION EFFICACY ........................... 6-3
OPERATIONAL MEASUREMENTS ................................................................................ 6-4 Intensity ............................................................................................................................... 6-4 Dose ..................................................................................................................................... 6-4
WHOLE EFFLUENT TOXICITY TEST EXPERIMENTAL AND ANALYSIS MEHODS 6-4 Sampling Program................................................................................................................ 6-5 Dilution Water...................................................................................................................... 6-5 Toxicity Bioassays ............................................................................................................... 6-5 Test Organisms .................................................................................................................... 6-6
TABLE OF CONTENTS (Continued)
Section Page
Rainbow Trout Bioassays ................................................................................................... 6-6 Daphnia magna Bioassays ................................................................................................... 6-7 Data Analysis ....................................................................................................................... 6-7
7 DATA COLLECTION RESULTS AND DISCUSSION .................................................... 7-1
TRACER STUDY RESULTS ............................................................................................. 7-1
SYSTEM OPERATION RESULTS .................................................................................... 7-2 Flow ..................................................................................................................................... 7-2 Lamp Cleaning Results ........................................................................................................ 7-2 Operating Intensity............................................................................................................... 7-3
WATER QUALITY RESULTS........................................................................................... 7-3 Water Quality Data .............................................................................................................. 7-3 Comparison of Water Quality to Disinfection Requirements............................................... 7-5 Impact of TSS on %T........................................................................................................... 7-5 Influence of Iron on %T and TSS ........................................................................................ 7-6 Fecal Coliform Data............................................................................................................. 7-6
DISINFECTION RESULTS................................................................................................ 7-7 Raw Disinfection Results ..................................................................................................... 7-7 Effect of Dose and Water Quality on Disinfection............................................................... 7-7
PHOTOREACTIVATION................................................................................................... 7-8
EFFECTS OF LAMP FOULING ........................................................................................ 7-9
TOXICITY TESTING RESULTS ....................................................................................... 7-9 Toxicity to Rainbow Trout................................................................................................... 7-9 Toxicity to Daphnia magna ................................................................................................. 7-11
SUMMARY OF RESULTS................................................................................................. 7-12 Operation.............................................................................................................................. 7-12 Water Quality ....................................................................................................................... 7-12 Effluent Toxicity .................................................................................................................. 7-12 Disinfection and Operating UV Doses................................................................................. 7-13
8 UV FACILITY IMPLEMENTATION AND COST ANALYSIS....................................... 8-1
SOUTHTOWNS WWTP DISINFECTION ALTERNATIVES.......................................... 8-1 Alternative 1 - Chlorination/Dechlorination ........................................................................ 8-1 Alternative 2 – Low Pressure-Low Intensity UV System .................................................... 8-2 Alternative 3 – Low Pressure-High Intensity UV System ................................................... 8-3 Alternative 4 – Medium Pressure-High Intensity UV System ............................................. 8-4
COST ANALYSIS OF SOUTHTOWNS UV DISINFECTION ALTERNATIVES........... 8-5 Construction Costs ............................................................................................................... 8-6 Personnel (Operations) Requirements.................................................................................. 8-7 Power Use and Cost ............................................................................................................. 8-7 Lamp Replacement Costs..................................................................................................... 8-8 Quartz Sleeve Cleaning........................................................................................................ 8-8 Sodium Hypochlorite and Sodium Bisulfite Costs............................................................... 8-9
TABLE OF CONTENTS (Continued)
Section Page
Miscellaneous O&M Costs .................................................................................................. 8-9 Life Cycle Cost Comparison ................................................................................................ 8-9
UV EQUIPMENT AND O&M COSTS FOR VARIOUS WWTP SIZES .......................... 8-10
9 CONCLUSIONS AND RECOMMENDATIONS...................................................................... 9-1
CONCLUSIONS ................................................................................................................. 9-1
RECOMMENDATIONS ..................................................................................................... 9-4
REFERENCES
LIST OF TABLES
Page 2-1 UV Dose to Achieve 3-Log Inactivation of Various Microorganisms................................. 2-5 2-2 Inorganic Composition of Lamp Fouling Material............................................................... 2-9 2-3 Photoreactivation in Wastewater Organisms........................................................................ 2-12 4-1 Filtered and Unfiltered Effluent Wastewater Quality at the Southtowns WWTP................ 4-2 6-1 Standard Methods................................................................................................................. 6-2 6-2 Disinfection Efficiency Sampling ........................................................................................ 6-3 6-3 Photoreactivation Studies..................................................................................................... 6-4 7-1 Tracer Study Conditions....................................................................................................... 7-1 7-2 Tracer Study Results ............................................................................................................ 7-1 7-3 Average Flow (in gpm) in the UV Systems ......................................................................... 7-2 7-4 Average Lamp Cleaning Frequency (in days/cleaning) ....................................................... 7-3 7-5 Summary of Water Quality Data (average, with range in parentheses) ............................... 7-4 7-6 Summary of Statistics for Correlations Between Measures of %T and TSS........................ 7-5 7-7 Summary of Statistics for Influent Fecal Coliforms............................................................. 7-6
7-8 Summary Statistics for Disinfection Performance ............................................................... 7-7 7-9 Results of Photoreactivation and Dark Reactivation Studies ............................................... 7-9 7-10 Toxicity to Rainbow Trout................................................................................................... 7-10 7-11 Toxicity to Daphnia magna ................................................................................................. 7-11 7-12 Toxic Events in Wastewater Streams at the Southtowns WWTP During the Operation
of the Pilot UV Treatment Systems ....................................................................... 7-12 7-13 Summary of Delivered UV Doses........................................................................................ 7-13 7-14 Summary of Operating UV Doses........................................................................................ 7-14 8-1 Life Cycle Cost (2004 Dollars) Analysis for UV Disinfection Alternatives ........................ 8-6 8-2 Comparison of Estimated Equipment Costs......................................................................... 8-11 8-3 Comparison of Estimated Annual Costs ($/year) ................................................................. 8-11 8-4 Comparison of Estimated Present Worth ............................................................................. 8-12 8-5 Comparison of Estimated Normalized Equipment and O&M Costs ($/1,000 gal) .............. 8-12
LIST OF FIGURES
Following Page No.
2-1 Electromagnetic Light Spectrum.......................................................................................... 2-1 2-2 Formation of Thymine-Thymine Dimer from Adjacent Thymine Residues ........................ 2-2 2-3 Impact of Particles on UV Disinfection ............................................................................... 2-7 2-4 Impact of Tailing on UV Disinfection ................................................................................. 2-7
2-5 Various UV System Configurations..................................................................................... 2-8 2-6 Common UV Lamp Orientations ......................................................................................... 2-9 4-1 Current Southtowns WWTP Treatment Process Schematic................................................. 4-1 4-2 Southtowns WWTP Site Plan .............................................................................................. 4-2 5-1 UV Pilot Plant Schematic ................................................................................................... 5-2 5-2 Interior of Lp-Li UV Pilot Unit............................................................................................ 5-2 5-3 Low Pressure Pilot Units ................................................................................................... 5-2 5-4 Mp-Hi Pilot Unit Lamps ................................................................................................... 5-2 6-1 Photograph of Rainbow Trout Toxicity Test........................................................................ 6-6 6-2 Photograph of Daphnia magna Toxicity Test ...................................................................... 6-7 7-1 Tracer Study Results for the Lp-Li System.......................................................................... 7-1
7-2 Tracer Study Results for the Lp-Hi System ......................................................................... 7-1
7-3 Tracer Study Results for the Mp-Hi System ........................................................................ 7-1
7-4 Flow Through the Lp-Li System.......................................................................................... 7-2 7-5 Flow Through the Lp-Hi System ......................................................................................... 7-2 7-6 Flow Through the Mp-Hi System ........................................................................................ 7-2 7-7 Lamp Cleaning in the Lp-Li System .................................................................................... 7-2 7-8 Lamp Cleaning in the Lp-Hi System.................................................................................... 7-2 7-9 Lamp Cleaning in the Lp-Li System – Expanded Scale....................................................... 7-2 7-10 Lamp Cleaning in the Mp-Hi System................................................................................... 7-2 7-11 Operating Intensity of the Mp-Hi System ............................................................................ 7-3 7-12 Influent Hardness ................................................................................................................. 7-3 7-13 Influent Total Iron Concentration......................................................................................... 7-3 7-14 Influent Unfiltered Percent Transmittance ........................................................................... 7-3
7-15 Influent Lab-Filtered Percent Transmittance........................................................................ 7-3 7-16 Influent Total Suspended Solids .......................................................................................... 7-3 7-17 Relationship Between the %T or Delta %T and TSS for the Low Pressure Systems........... 7-5 7-18 Relationship Between the %T or Delta %T and TSS for the Mp-Hi System....................... 7-5 7-19 Relationship Between the %T or Delta %T and Total Iron for the Low Pressure Systems . 7-6 7-20 Relationship Between the %T or Delta %T and Total Iron for the Mp-Hi System.............. 7-6 7-21 Relationship Between Total Iron and TSS ........................................................................... 7-6 7-22 Influent Fecal Coliform Concentrations............................................................................... 7-6 7-23 Effluent Fecal Coliform Concentrations .............................................................................. 7-7 7-24 Fecal Coliform Log Kill ................................................................................................... 7-7 7-25 Log Kill Plot for the Lp-Li System ...................................................................................... 7-7 7-26 Log Kill Plot for the Lp-Hi System...................................................................................... 7-7 7-27 Influence of %T on the Log Kill Plot for the Lp-Hi System................................................ 7-8 7-28 Log Kill Plot for the Mp-Hi System..................................................................................... 7-8 7-29 Log Kill as a Function of TSS for the Mp-hi System........................................................... 7-8 7-30 Log Kill as a Function of the UV Intensity Display Reading for the Lp-Li System ............ 7-9 8-1 Schematic Layout of UV Disinfection Facilities.................................................................. 8-2
APPENDICES
APPENDIX A – SUMMARY OF RECENT DISINFECTION STUDIES
APPENDIX B – MANUFACTURERS INFORMATION OF UV PILOT UNITS AND UV MANUFACTURER CUT SHEETS
APPENDIX C – SOUTHTOWNS WWTP UV DEMONSTRATION RAW DATA SUMMARY
SUMMARY
A project to determine the long-term benefits and costs associated with three different ultraviolet radiation
(UV) disinfection alternatives with respect to chlorination/dechlorination was performed at the Erie County
Department of Environment and Planning’s (ECDEP’s) Southtowns Wastewater Treatment Plant (WWTP),
located in Hamburg, New York. The three UV disinfection technologies evaluated used the following lamp
types: 1) low pressure-low intensity (lp-li), 2) low pressure-high intensity (lp-hi) and 3) medium pressure-
high intensity (mp-hi).
Chlorination has been the preferred disinfection method used for treating WWTP effluent, but concerns
about worker and public safety and the potential for chlorinated effluent to be toxic to aquatic life have
called its use into question. As a result, regulatory agencies are adopting stringent chlorine residual
effluent limitations, and require risk management plans for bulk storage of chlorine gas or stringent storage
and handling requirements for sodium hypochlorite. More stringent chlorine residual discharge limits will
require implementation of dechlorination or an alternative disinfection technology.
Although chlorine, sometimes followed by dechlorination, continues to be used at most municipal WWTPs,
use of other means, such as UV disinfection, is increasing. UV is a technology capable of providing
effective WWTP effluent disinfection while reducing safety and environmental toxicity issues. Oftentimes,
UV disinfection equipment are readily retrofit into existing WWTP chlorine contact chambers, which helps
reduce capital costs. However, a host of other issues must be carefully considered to verify that UV
facilities are safe, reliable and economical. These issues include the cost of power and lamp replacement,
lamp fouling, ability of the water to allow transmission of UV radiation, tailing, photoreactivation and
regrowth of disinfected microorganisms, and dose selection. Wastewater treatment professionals
understandably are cautious regarding implementation of new processes and require independently
obtained treatability data before process changes will be considered.
Data to evaluate the three UV disinfection technologies was collected using a pilot plant at the Southtowns
WWTP. The pilot plant was operated under a variety of conditions, including UV dose and effluent type
(filter vs. bioclarifier).
A summary of the key findings and conclusions are as follows:
S-1
PILOT PLANT HYDRAULICS
x� Tracer studies were performed on the three UV pilot units (lp-li, lp-hi, and mp-hi) to determine if
the actual hydraulic residence time (HRT) was similar to the nominal HRT (volume/average flow),
and determine how close to plug flow the reactors are operating. Accurate HRT measurement is
critical because it is used in calculating UV dose.
x� The tracer tests showed that the UV pilot-units nominal HRT appears to be a reasonable estimate
of system HRT.
x� The reactors used in this study show an intermediate amount of dispersion, which is reasonably
close to plug flow conditions.
DISINFECTION RESULTS AND OPERATING DOSE
x� Fecal coliform log kills of 2.7 – 2.9 were required to achieve an effluent of 200 most probable
number per 100 milliliters (MPN/100 mL) based on average influent fecal coliform concentrations
in the UV reactors.
x� UV was shown to effectively disinfect Southtowns WWTP filtered water and bioclarifier effluent
to meet a fecal coliform discharge limit of 200 MPN/100 mL. The estimated UV operating dose
to achieve the required log kill for the lp-li, lp-hi and mp-hi systems were 26 mW-s/cm2, 30 mW
s/cm2, and 32 mW-s/cm2, respectively.
x� The difference in required doses between the three test systems was not unexpected. The required
doses are expected to be related to intensities in the germicidal range. The lp-li lamps emit the
greatest percentage of UV light in the germicidal range, while the mp-hi lamps emit the lowest
percentage.
IMPACT OF WATER QUALITY AND TAILING ON UV PERFORMANCE
x� Tailing is a phenomenon in which significant increases of UV dose result in little additional
inactivation of microorganisms.
x� All three UV systems exhibited tailing at log kills of fecal coliform greater than about 2 (99%).
However, data showed log kills of 2.7 – 2.9 are required to achieve an effluent of 200 MPN/100
mL in Southtowns WWTP effluent. Therefore, tailing would reduce the efficiency of UV
S-2
disinfection. Five factors were investigated for their effects on tailing: dose, system influent
(bioclarifier vs. filter effluent), total suspended solids (TSS), iron and percent transmittance (%T).
x� The bioclarifier effluent and filter effluent had similar TSS values, which was unexpected. One
possible reason for this occurrence is the age of the filter media at the Southtowns WWTP (20
years). Subsequent to the demonstration, the ECDEP commenced implementation of
modifications to improve filtration improvements and capacity.
x� The influent for all three systems exhibited %T values of less than 65% for every sample
regardless of source (bioclarifier or filter effluent). Thus, the water quality was poor (as indicated
by %T) with regard to the potential for UV disinfection. No discernable difference in UV
performance due to type of influent was observed during this study. It is noteworthy that
laboratory filtration raised the %T to above 65% in all but four samples for the three UV systems.
x� The filter effluent had slightly better water quality on average in terms of %T and lab-filtered %T.
The effects of filtration appear to show more strongly as removal of UV-absorbing substances
(increasing %T) rather than removal of solids only. This suggests that the planned filter media
replacement would further improve %T, thus better UV disinfection performance would be
expected using filter effluent. These conclusions are tentative because the water quality of
bioclarifier effluent and filter effluent were not measured at the same time.
x� The surprising water quality result in this study was the correlation between total iron and TSS.
This correlation may be explained in two ways. First, the plant influent TSS may have a constant
iron content of between 6% and 7%. Second, dosing of ferric salts in the plant for phosphate
control may be tied to TSS in the plant influent. Due to the correlation between iron and TSS, it is
difficult to separate the effects of TSS and iron on system performance and maintenance.
x� In general, dose was a better predictor of disinfection performance and tailing than system influent
(bioclarifier effluent vs. filter effluent), TSS (data with TSS greater than 20 mg/L vs. data with
TSS less than 20 mg/L), iron (data with iron greater than 2.0 mg/L vs. data with iron less than 2.0
mg/L), or %T (data with %T greater than 55% mg/L vs. data with %T less than 55%).
EFFLUENT TOXICITY
x� Effluent toxicity samples were collected from the lp-li, lp-hi and mp-hi pilot units and compared
to the toxicity of chlorinated WWTP effluent. Samples were collected over a 14-month period and
S-3
bioassays of rainbow trout and Daphnia magna performed based on standardized tests developed
by the United States Environmental Protection Agency and Environment Canada.
x� During all sampling events, the chlorine treated wastewater was toxic to rainbow trout and
Daphnia magna. No acute toxicity of Daphnia magna was seen in any of the UV treated
effluents. Three out of 35 samples of UV treated effluent showed toxicity to rainbow trout;
however, causes other than UV disinfection may have resulted in the toxic events.
x� The data suggests that, when compared to chlorine treatment of the Southtowns WWTP effluent,
UV treatment significantly reduces whole effluent toxicity to rainbow trout and daphnia. This
suggests that there are real ecotoxicological advantages to using UV in place of chlorination for
the disinfection of municipal wastewater.
PHOTOREACTIVATION
x� Secondary growth studies were conducted to determine whether apparently inactive coliforms
actually were viable. These studied consisted of photoreactivation, dark repair and regrowth
experiments.
x� The demonstration showed that neither photoreactivation, dark repair nor regrowth was significant
during this project.
OPERATION
x� The primary O&M requirement in UV disinfection for this demonstration was lamp cleaning.
Increased fouling of the lamps resulted in reduced intensity transmitted to the microorganisms,
thus reducing log kills. In this study, lamp cleaning was successful in restoring measured UV
intensity. The mp-hi system required frequent lamp cleaning, likely because of its higher
operating temperature. The use of automatic cleaning equipment would greatly facilitate lamp
maintenance.
COST ANALYSIS
x� Of the three UV alternatives evaluated for the Southtowns WWTP, the lp-hi system had the lowest
annual cost ($396,000), total present worth ($4,760,000) and normalized cost ($0.060/1,000 gal).
The lp-hi and mp-hi had similar estimated construction costs, but the lp-hi system had almost a
S-4
45% lower estimated O&M cost than the mp-hi system; power costs for the mp-hi system were
estimated to be about four times higher than the lp-hi alternative.
x� The lp-li system is not considered cost effective at the large flow rates experienced at the
Southtowns WWTP because of the number of lamps required. The lp-li alternatives would require
approximately 2,160 lamps, while the lp-hi system would need 360 lamps (6 times less) and the
mp-hi alternative would need 176 lamps (12 times less).
x� The chlorination/dechlorination alternative had the lowest overall estimated annual cost
($309,000), total present worth ($3,900,000) and normalized ($0.047/1,000 gal) for the
Southtowns WWTP. This is followed by the lp-hi alternative. The primary reason why
chlorination/dechlorination had the lowest cost was because of its significantly lower estimated
capital cost ($1,150,000 for chlorination/dechlorination and $3,350,000 for the lp-li system). The
difference in capital cost offset the estimated 40% O&M cost savings that would be realized using
the lp-hi system (chlorination/dechlorination = $174,000 per year, lp-hi system = $104,000 per
year).
x� The Southtowns WWTP does not have an existing chlorine contact chamber; the outfall pipe is of
sufficient length to currently meet chlorine contact time requirements. About half of the
$3,350,000 estimated construction cost for the lp-hi system was associated with modifying a
significant portion of the plant’s outfall to accommodate a UV disinfection chamber. One of the
key advantages for UV disinfection is its ability to be retrofitted into existing chlorine contact
tanks; this advantage cannot be realized at the Southtowns WWTP. If the plant had an existing
chlorine contact chamber, the capital cost for the lp-hi system could be reduced by up to
$1,600,000. This reduction likely would have made the lp-hi system competitive, if not lower in
cost, than the chlorination/dechlorination alternative. Based on this perspective, it appears that
UV disinfection is a cost competitive alternative to chlorination/dechlorination at WWTPs with
existing chlorine contact chambers.
RECOMMENDATIONS
Based on the results of this demonstration, the following are recommended:
x� Wastewater utilities should consider implementing UV disinfection for WWTP effluent in lieu of
chlorine, particularly where a treatment plant must implement dechlorination and uses an existing
chlorine contact chamber. UV was shown to effectively disinfect Southtowns WWTP filtered
water and bioclarifier effluent while mitigating the effluent toxicity concerns associated with
residual chlorine.
S-5
x� Because of the variable nature of wastewater composition between communities, the required UV
doses must be determined on a site-specific basis. Key parameters that must be accounted for
include TSS, percent transmittance, iron and hardness.
x� Selection of the most appropriate UV disinfection technology depends on several factors,
including flow, existing WWTP configuration, discharge limitations, unit power cost and required
UV dose.
x� Additional study is needed to better define the separate effects of TSS and iron on UV system
performance and maintenance, particularly in WWTP that use ferrous compounds for phosphorus
removal.
x� As the filter media ages, the effluent quality can deteriorate, especially TSS and % transmittance.
Additional study is needed to determine the impact of aging filter media on UV disinfection
performance.
S-6
Section 1
INTRODUCTION
Effluent from municipal wastewater treatment plants (WWTPs) using the activated sludge process is
typically disinfected to protect water supplies, beaches, and aquatic organisms. Chlorine has been the
preferred disinfectant used, but concerns about worker and public safety and the potential for chlorinated
WWTP effluent to be toxic to aquatic life have called its use into question. As a result, regulatory agencies
are adopting stringent chlorine residual effluent limitations and require risk management plans for bulk
storage of chlorine gas, as well as stringent storage and handling requirements for sodium hypochlorite.
The New York State Department of Environmental Conservation (NYSDEC) has, and is expected to
continue reducing chlorine residual limits in WWTP discharges, which will require implementation of
dechlorination or an alternative disinfection technology.
Although chlorine, which sometimes is followed by dechlorination, continues to be used at most municipal
WWTPs, use of other disinfection means is increasing. Maintaining high quality WWTP effluent
discharges while minimizing energy usage and costs requires the use of innovative technologies, one such
technology being ultraviolet radiation (UV). This technology is capable of providing effective disinfection
of WWTP effluent while reducing safety and environmental toxicity issues.
The design and operation of disinfection systems requires great care to ensure that the facilities are safe,
reliable and economical. Municipal wastewaters in New York State vary significantly depending upon the
type of community served and the type of treatment employed. Although there are many potential benefits
of using UV for WWTP effluent disinfection, there are also potential disadvantages associated with cost,
lamp fouling and photoreactivation of target microorganisms. Therefore, wastewater treatment
professionals are understandably careful regarding the implementation of new processes and require
independently obtained treatability data and pilot-scale evaluations before changes in treatment processes
will be considered. These professionals require information on the benefits, efficacy, capital and operating
costs, energy use and potential impacts to water quality on a long-term basis.
To evaluate the costs and benefits of using UV instead of chlorine for disinfection of WWTP effluent, the
New York State Energy Research and Development Authority (NYSERDA), National Grid and the Erie
County Department of Environment and Planning (ECDEP) sponsored a pilot-scale demonstration at the
Erie County Southtowns WWTP. The demonstration included the pilot-scale evaluation of three different
UV lamp types: low pressure-low intensity (lp-li), low pressure-high intensity (lp-hi), and medium
1-1
pressure-high intensity (mp-hi). URS Corporation (URS), the University at Buffalo (UB) and StanTec, Inc.
(StanTec), performed the demonstration jointly.
This report summarizes the results of the pilot-scale demonstration and evaluation of the benefits and costs
associated with the three different UV lamp types. Included are a comparison of long-term performance,
benefits, energy use, costs and environmental impacts associated with three lamp types with respect to
chlorination/dechlorination. A comparison of UV disinfection performance on treating filtered and
unfiltered (secondary clarifier effluent) wastewater also is presented. In addition, the report includes a
summary of equipment and operating and maintenance costs using UV disinfection at various sized
municipal WWTPs.
1-2
Section 2
BACKGROUND
CHLORINE AND UV DISINFECTION
Chlorine Disinfection Issues
As noted in the introduction, chlorine disinfection is the most common form of wastewater disinfection
today. Chlorination is a well established technology and an effective disinfectant. However, the use of
chlorine for disinfection is being reevaluated because of several key concerns. First, chlorine poses a risk
to the health and safety of WWTP personnel and the surrounding community. Accidental release of
chlorine can occur through volatilization from chlorine contact facilities or through leaks in the storage
cylinders or feed lines. Inhalation of chlorine damages the upper and lower respiratory tracts and causes
severe skin irritation upon physical contact, and can be lethal to humans. Because of this danger, larger
water and wastewater facilities are required to maintain risk management plans that address chlorine use
and storage.
Second, chlorine can adversely impact receiving streams and can adversely impact biota. The residual
chlorine and chloramines from the disinfection process are toxic to many aquatic organisms, including fish,
oysters and copepods (Johnson and Jensen, 1986). Residual concentrations as low as 0.002 milligrams per
liter (mg/L) have reportedly induced toxic effects in aquatic organisms (TFWD, 1986). Vegetation also can
be affected by residual chlorine.
Third, chlorine reacts with organic material in the environment to form disinfection byproducts (DBPs) that
have potentially adverse impacts to human health. The key DBPs of concern are the formation of
trihalomethanes (THMs), such as chloroform and haloacetic acids (HAAs).
Ultraviolet (UV) Radiation Disinfection
UV light was discovered as part of the electromagnetic spectrum by John Ritter in 1801 (Fleishman, 1996).
UV light refers to radiation with wavelengths between 30 and 400 nanometers (nm), which are shorter than
visible light. UV light commonly is referred to as black light because it cannot be seen by the human eye.
The UV spectrum is divided into three parts: UV-A (315 – 400 nm), UV-B (280 – 315 nm) and UV-C (30 –
280) (Thampi, 1988). UV light produced by the sun causes the human skin to tan or burn. However, the
more harmful effects of the sun (e.g., skin cancer and eye cataracts) are specifically from the UV-C part
(Fleishman, 1996). Figure 2-1 presents a schematic of the UV light spectrum.
2-1
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-1
UV disinfection is a physical form of disinfection, as opposed to the chemical form of chlorine. Some
molecules, when subjected to UV light, will absorb its energy. Once absorbed, the electronic energy is
sufficient to break bonds and promote the formation of new bonds within the molecule, leaving it damaged.
For this reason, UV-C light is called phototoxic (toxic light) (Larson and Berenbaum, 1988). The most
important molecules of living cells, deoxyribonucleic acid (DNA) and ribonucleic acid (RNA), are very
sensitive to phototoxicity (Larson and Berenbaum, 1988). The most common effect of UV-C is the
formation of a cyclobutyl ring between two adjacent thymine nucleic acids located on the same strand of
DNA/RNA, as shown on Figure 2-2 (Voet and Voet, 1995). The resulting structure, called a thymine
dimer, locally distorts the helical structure of the DNA/RNA molecule preventing the proper attachment of
transcriptional and replicating enzyme complexes. This damage most commonly results in inhibition of
the transcription and replication of the genetic molecules within the affected cell, which results in death of
that single cell (Larson and Berenbaum, 1988).
Bacteria, protozoa and viruses are also susceptible to UV-C radiation. Sufficient UV exposure to these
single-celled organisms ensures death, particularly at a UV wavelength of 253.7 nm. Once this was
discovered, scientists used the germicidal effects of UV light to their advantage. Lamps were invented that
emit artificial UV light. These lamps were, and still are, used for sterilization of food packaging, as well as
the food they contain, and equipment used in the medical field (Fleishman, 1996). The sterilization of
water using UV radiation began in 1909 (White, 1992). Nevertheless, it was only within the last twenty
years, with awareness of the health and environmental consequences of using chlorine and the significant
improvements in UV reactor design and lamp efficiency, that the first full scale UV disinfection unit was
constructed for use in the wastewater treatment industry (Fahey, 1990). Since then, UV systems are
becoming increasingly more popular, and the trend is expected to continue through this century (Fahey,
1990).
UV disinfection of wastewater has become an accepted alternative to chemical methods of disinfection for
secondary and tertiary quality wastewater. As an example, over 1,000 UV systems manufactured by Trojan
Technologies, Inc. are reportedly in operation throughout North America, Europe and Asia. The continued
increase in interest and use of UV as a disinfectant is because of its many advantages over chlorination.
The major advantages of UV over chlorination as a disinfectant can include:
x� An environmentally safe, non-chemical, physical process that produces no toxic side effects and
byproducts
x� A safe and simple system for operators to use
x� Ability to achieve the required disinfection level in a few seconds while chlorine requires a
minimum of 15 minutes
x� Installed in flow-through channels without the need for contact tanks
2-2
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-2
x� Constructed on a minimum amount of land and without requiring buildings
x� More effective than chlorination on a wide range of organisms, including some viruses that are
resistant to chlorine
ALTERNATIVE UV DISINFECTION TECHNOLOGIES
The most important element of UV systems is the light source or lamp. DNA and RNA molecules exhibit a
maximum absorbance of UV-C light between 250 and 260 nm (Thampi, 1990). To maximize the
efficiency of the system, the light source must emit at this wavelength range. Three types of UV lamps are
readily commercially available: low pressure-low intensity (lp-li), low pressure-high intensity (lp-hi), and
medium pressure-high intensity (mp-hi). The term pressure refers to the pressure of gasses inside the lamp.
Intensity refers to the energy output. The distinction between the technologies is primarily the germicidal
intensity given off by each lamp type, which correlates to the number of lamps required and overall UV
system size. The lamp type selected would be determined on a site-specific basis.
The oldest and most energy efficient lamps used for UV disinfection are the lp-li lamps. These lamps
contain mercury vapor and argon gas that emits nearly monochromatic radiation at 253.7 nm and operate
between temperatures of 40 oC and 60 oC when excited with electronic energy (Hanzon and Vigilia, 1999).
Of the total emissions from the low-pressure/low-intensity lamps, approximately 85% are at the 253.7 nm
wavelength, which is near the peak for germicidal effectiveness. The actual lamp looks very similar in
appearance to a fluorescent tube light bulb. Fluorescent tubes have a phosphor coating to convert the UV
energy emitted by the mercury vapor to visible light. UV lamps are made of quartz glass because of
quartz’ ability to transmit UV light.
The power draw of the lp-li lamp is around 88 Watts and the germicidal output is approximately 20 to 25%
of the lamp rating (Muller, 1999 and Thampi, 1990). These lamps emit approximately 0.2 germicidal watts
per centimeter arc length (W/cm) of radiation energy (Hanzon and Vigilia, 1999). The intensity of the
lamp is very unstable for the first 100 hours; for this reason, 100% intensity is usually measured after the
first 100 hours of use. The 100% intensity value is supplied by the lamp manufacturer.
The intensity of the UV lamp is affected by time and temperature. After 100 hours, the lamp will decline
gradually in intensity with age (Darby et al., 1993). The estimated lifetime of the lamp is approximately
13,000 hours, or about 1-½ years (Muller, 1999). Over this lifetime the intensity of the lamp will drop to
about 75% of it’s original intensity at 100 hours (Braunstein et al., 1996). The optimum operating
temperature is 40o C. Temperatures higher or lower than the optimum will reduce the lamp’s intensity by
1% to 3% per degree (Thampi, 1990). The typical cost for a lp-li lamp is about $45 (Muller, 1999).
2-3
The other two commercially available UV technologies, the lp-hi lamp and the mp-hi lamp, are
modifications of the original lp-li lamps. Both of the high intensity lamps emit a broader, polychromatic
radiation. Their higher intensities allow for a significant reduction in the total number of lamps required
for adequate disinfection (Hunter et al., 1998). However, because the lamps use a substantial amount of
their total energy producing light outside the germicidal range they are not considered as efficient as the lp
li lamps.
The high intensity lamps allow for a significant reduction in the total number of lamps required for
adequate disinfection. However, they also use a significant amount of energy to emit radiation outside the
germicidal range and are thus, less efficient than lp-li lamps. The high intensity lamps can allow higher
capacity WWTPs to cost-effectively implement UV disinfection. Larger WWTPs, which previously would
have required thousands of lp-li lamps, require only hundreds of high intensity lamps.
The lp-hi lamp operates at pressure similar to its low intensity counterpart. However, the operating
temperature range is 180 – 200 oC, which is significantly higher than the lp-li lamp (Hanzon and Vigilia,
1999). The power draw of the lp-hi lamp is about 250 W and the germicidal output is approximately 13
W/cm. The lp-hi lamps have an average lifetime of about 8,000 hours (0.9 years), with gradually falling
lamp intensities. The low pressure-high intensity lamps cost approximately $185.
The polychromatic medium pressure-high intensity lamp operates at temperatures between 600 and 800 oC.
The lamps contain mercury vapor and argon gas that produce polychromatic radiation, although
concentrated at select peaks throughout the germicidal wavelength region. The power draw required by
this lamp is approximately 2,800 W. The germicidal output of mp-hi lamps is about 16 W/cm, which is
about 80 times higher than lp-li lamps. The lamps have an average lifetime of about 8,000 hours (0.9
years) with intensity gradually declining over time. The lamp cost is approximately $225.
FACTORS THAT IMPACT UV DISINFECTION
Disinfection Efficacy
Many studies have been published that illustrate the effectiveness of UV disinfection. A number of recent
studies are summarized in Appendix A. In general, the disinfection efficiency of UV, as reported in
Appendix A, was quite good. Of the studies presented, Nieuwstad et al. (1991) reported the worst water
quality; total suspended solids (TSS) concentrations were as high as 60 milligrams per liter (mg/L). Not
surprisingly, the disinfection effectiveness achieved in the poor quality water was correspondingly low.
The water quality for the remainder of the studies was below or at the recommended 20 mg/L limit with the
2-4
exception of a test by Job et al. (1996), which also resulted in poor disinfection when compared with the
other runs in their study. Most of the experiments yielded fairly consistent results.
Also apparent from the summary in Appendix A is the lack of information on lamp types other than lp-li.
In only two cases mp-hi lamps were investigated and compared to lp-li lamps (Havelaar et al., 1990 and
Nieuwstad et al., 1991). In both instances the mp-hi lamps were reported to be less efficient. In the
Nieuwstad et al. study the influent water quality for the mp-hi unit was appreciably lower than that for the
other units. Since water quality is known to significantly affect the disinfection efficiency of UV systems,
comparisons between units that are fed differing water quality may not be valid. Both of these studies were
conducted when the mp-hi lamp technology was relatively new. Since 1990, the popularity of mp-hi
systems has grown as these systems have been improved.
The effectiveness of UV disinfection is directly related to the dose absorbed by the target microorganisms.
The UV dose delivered within a reactor is defined as the product of the average UV intensity within the
reactor multiplied by the contact time of the liquid passing through the reactor. Dose units are often given
as milliwatt-seconds per square centimeter (mW-s/cm2). The range of UV dose required to achieve a five
to six log reduction (99.999% to 99.9999%) in the number of dispersed non-particle associated coliform
organisms typically ranges from 10 to 40 mW-s/cm2. Unfortunately, in municipal wastewater treatment,
many of the coliform organisms are either clumped or particle associated, which necessitates increasing UV
dosage. The required UV dosage for any specific treatment plant will vary depending upon the treatment
process, quality of water being disinfected and the targeted microorganisms. Table 2-1 summarizes the
estimated amount of UV dosage required to achieve 3-log (99.9%) inactivation of several common types of
microorganisms.
Table 2-1: UV Dose to Achieve 3-Log Inactivation of Various Microorganisms
Microorganism Dose
(mW-s/cm2)
Microorganism Dose
(mW-s/cm2)
Bacteria Viruses
Bacillus anthracis 8.7 Bacteriophage 6.6
Bacillus subtillis, spores 58 Hepatitis virus 8.0
Bacillus subtillis, vegetative 11 Influenza virus 6.6
Clostridium tetani 22 Polio virus 21
Corynebacterium diphtheriae 6.5 Rota virus 24
Escherichia coli 7 Protozoa
Legionella pnuemophila 3.8 Nematode eggs 92
Sarcina lutea 26 Paramecium 200
2-5
Microorganism Dose
(mW-s/cm2)
Microorganism Dose
(mW-s/cm2)
Mycibacterium tuberculosis 10 Yeast
Pseudomonas aeruginosa 10.5 Baker’s yeast 8.8
Salmonella enteritidis 7.6 Saccharomyces 17.6
Salmonella typhosa 6
Shigella dysenteriae 4.2
Shigella flexneri (paradysenteriae) 3.4
Staphlococcus aureus 7
Vibrio cholerae (V. comma) 6.5
Several models have been developed to evaluate disinfection efficacy. These models include the following
x� Chick-Watson Model
x� Continuous Flow Stirred Tank Reactors in Series
x� Two Dimensional Continuum Model
x� Probabilistic Particle-Centered Model
UV Transmittance, Suspended Solids and Particle Shading
The amount of UV energy required to inactivate microorganisms is dependent on the UV transmittance of
the liquid and suspended solids concentration. Many of the constituents found in wastewater absorb UV
light, which results in a lower UV intensity.
UV transmittance represents the percentage of UV energy in the water that reaches the microorganisms.
The lower the transmittance, the lower the amount of UV light that reaches the microorganism. UV
transmission is dependent on the spacing of lamps and the water quality of the liquid. The water quality
characteristics that affect transmittance include iron, hardness, suspended solids, humic materials and
organic dyes.
Iron is considered to be very significant with respect to UV absorbance (Jacangelo et al., 1995). Dissolved
iron can absorb UV light and precipitate on the UV system quartz tubes. Hardness affects the solubility of
metals that absorb UV light and can precipitate carbonates on quartz tubes. Organic humic acids and dyes
also absorb UV light.
Particles can scatter UV light or shade microorganisms from the radiation. Bacteria and viruses in
wastewater, are often bonded together as a floc, or associated with particulate matter. It has been estimated
that about 1% of all microorganisms in wastewater are associated with particles (Parker and Darby, 1995).
This means that in a typical wastewater that contains approximately 1x105 fecal coliform per 100 milliliters
2-6
(mL), one thousand of those fecal coliform will be particle associated. These organisms are more difficult
to disinfect than their free-floating counterparts. Particles may shade the microorganisms by blocking the
light, as shown in Figure 2-3. Particles also can reflect or absorb the UV light, thus protecting any
organisms behind it. Some organisms can become embedded within, or absorbed upon the particles
themselves (Darby et al., 1993). These microorganisms are effectively shielded from the damaging effects
of UV light if light penetration is incomplete.
The combination of these effects of particles is thought to be the dominant reason for the observed tailing
in the dose-response curve (Loge et al., 1996). As shown on Figure 2-4, the presence of particles creates a
tailing region in which significant increases of UV dose result in little additional inactivation of
microorganisms. This curve shows that the number and distribution of particles is critical to effective
disinfection. Figure 2-4 also shows the effect of UV intensity (Tchobanoglous et al., 1999). Increasing the
UV intensity tenfold has little effect on the particle associated coliforms. The reason for the minor
improvements is that wastewater particles adsorb UV light up to 10,000 times or more than the liquid.
The significance of suspended solids was revealed by Darby et al. (1993) when they tested the difference in
UV disinfection efficiency between unfiltered and filtered secondary effluent. They discovered UV
disinfection performance was improved when the wastewater was filtered prior to disinfection. Originally,
an increase in UV transmittance of the wastewater due to filtration was thought to be the cause of the
improved disinfection efficiency; however, UV transmittance was not found to be significantly different
(average increase of 2%). Therefore, they attributed the improvement to removal of large particles and,
hence, the reduction in particle shading and shielding effects (Darby et al., 1993). Parker and Darby (1995)
specifically examined the effects of particles on UV disinfection. Bacterial densities after extraction were
anywhere from 1.8 to 340 times greater than their initial concentrations, proving that many coliforms were
able to escape UV disinfection because of their particle association.
Research conducted by Ho et al., (1998) on indigenous male-specific coliphage has shown that viruses may
not associate as strongly with particulate matter as bacteria. No correlation between total suspended solids
(TSS) and the level of virus inactivation was found and good disinfection results were obtained even when
TSS concentrations were high. However, because of the demonstrated negative effects of particles on
bacteria, TSS concentrations greater than 20 mg/L should be avoided (White, 1992). Because of the
significant impact of particles, UV disinfection is typically not considered for overflow retention facility
effluent, which only undergoes primary treatment and has TSS concentrations well over 20 mg/L.
One of the biggest problems in UV disinfection is the difficulty measuring UV reactor intensity. There are
no instruments that directly measure average UV light intensity within a reactor (Qualls et al., 1989). UV
radiometers are probes that are used to detect UV light intensity at a given wavelength (usually 253.7 nm).
2-7
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FIG
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-4
However, this value is specific to the point in the reactor at which the measurement was taken and to the
water quality in the reactor at that point in time. Therefore, using a radiometer to estimate the average
intensity within a reactor at any given time is a difficult task. Three types of indirect approaches to
estimating average UV intensity have been developed, mathematical methods, biological assays, and
chemical actinometry (Braunstein et al., 1996). Of the three types of approaches, two mathematical
models, the point source summation (PSS) method and the single point source summation (SPSS) method,
as well as biological assays are most commonly applied, yet no one method has gained a dominant position.
UV intensity will decrease with distance due to dissipation and absorption. Therefore, some manufacturers
equip UV reactors with on-line UV radiometers at the surface of a quartz sleeve (Infilco Degremont, Inc.,
1996). These on-line probes measure the decrease in lamp intensity as a percentage of initial intensity.
This factor can then be incorporated into the average intensity for a more accurate calculation of dose. If
the reactor is not equipped with an on-line UV radiometer, the manufacturer may supply an intensity versus
age curve for the lamps and the decrease from initial lamp output intensity must be estimated from this
curve (Darby et al., 1993). This more approximate method may or may not include an additional
correction factor that estimates the effects of lamp fouling (Oppenheimer et al., 1997 and Darby et al.,
1993).
UV Reactor Hydraulics and Configuration
The hydraulic characteristics of a reactor can strongly influence disinfection effectiveness. The optimum
hydraulic scenario for UV disinfection involves turbulent flow with mixing while minimizing head loss.
To maximize effectiveness, UV reactors are preferred to operate at a Reynold’s Number of greater than
5,000. Reactor design, including inlet and outlet flow distribution, controls how close to plug flow the unit
operates. Inlet conditions are designed to distribute the flow and equalize velocities. UV system outlets are
designed to control the water level at a constant level with little fluctuation within the UV disinfection
reactor. Tracer studies are often used to evaluate UV reactor hydraulics.
UV disinfection systems employ a variety of physical configurations. Figure 2-5 is a compilation of many
of the UV configurations. The darker shaded areas in Figure 2-5 represent water and the lighter circles
containing the letter “L” represent lamps. Although all of these designs were built and tested, most never
made it out of the pilot scale. An open channel style of Unit 5 has been tested most extensively and
appears to have become the configuration of choice in recently published works. UV lamps are generally
arranged in linear configuration to avoid UV emission losses because of self absorption, reflection or
refraction that can occur if a UV lamp were twisted into loops or spirals to increase intensity along the
linear axis.
2-8
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The configuration in Unit 5 has been modified into two main geometric models for UV disinfection
systems. These two popular systems are shown in Figure 2-6. In System A, the lamps are fixed vertically
in the reactor, perpendicular to the flow, and in system [B], the lamps are situated horizontally in the
reactor, parallel to the flow. Ho et al. (1998) completed a study that compared one horizontal unit and two
vertical units. They found that hydraulic conditions within each reactor improved with increasing velocity.
However, the horizontal unit was far superior to both the vertical units. Disinfection trials demonstrated
that the horizontal unit in this study was more efficient than the vertical units and the authors surmised that
the differences in disinfection efficiency were due chiefly to the poor hydraulics of the vertical units (Ho et
al., 1998). Still some manufacturing companies of UV disinfection units claim that vertical arrays are less
likely to pass water that has not received an adequate UV dose, especially in the case of lamp failure
(Infilco Degremont, Inc., 1996), and can provide quick access to each individual lamp for significantly
easier maintenance. Most of the UV systems currently produced for wastewater treatment have the flow
lines running parallel to the lamp axes.
Lamp Fouling
The warm temperatures produced by UV lamps promote the precipitation of an inorganic, amorphous film
on the surface of the quartz sleeves when the lamps are placed directly within the wastewater stream
(Blatchley et al., 1996). The film results predominately from a build up of metal precipitates called scale
and, therefore, wastewater with a high hardness is particularly prone to lamp fouling. Blatchley et al.
(1996) analyzed the film for its inorganic composition. They found iron to be the most abundant metal and
reported the concentrations of the other constituents as relative normalities to iron. Table 2-2 summarizes
their results (Blatchley et al., 1996).
Table 2-2: Inorganic Composition of Lamp Fouling Material
Metal Relative
Normality to
Iron
Metal Relative
Normality to
Iron
Iron 1.0 Silicon < 0.1
Calcium 0.55 Potassium < 0.1
Aluminum 0.35 Barium < 0.1
Sodium 0.1 Manganese < 0.1
Magnesium 0.1 Zinc < 0.1
2-9
VERTI
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2-6
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In addition to the accumulation of mineral salts, lamp fouling is also caused by oil, grease, suspended solids
deposits, and biofilms (Mann and Cramer, 1992). If no tertiary treatment is provided, physical debris may
contribute to fouling as well. Lamp fouling significantly reduces the effectiveness of UV disinfection by
blocking the light rays. Most UV disinfection systems must be cleaned on a regular basis. Oppenheimer et
al. (1997) demonstrated that the percentage of lamp fouling has an approximate linear relationship with the
time elapsed after the lamps were last cleaned.
Job et al. (1995) compared the effectiveness of a UV pilot scale unit at five different treatment plants with a
wide variety of water quality characteristics. One of the five plants did not show any significant decrease
in efficiency, while fouling at two of the plants decreased efficiency by approximately 4 logs, with the
remaining two plants in between. Many effluent water quality parameters were measured, yet no obvious
conclusions could be drawn as to why some plants exhibited less fouling than others. Therefore, the
tendency of an effluent to promote lamp fouling is not easily predictable (Job et al., 1995). For this reason
it was recommended that a percent inactivation by percent fouling curve be developed using a pilot scale
unit to determine an appropriate cleaning frequency before full scale operation goes online (Oppenheimer
et al., 1997). The cleaning frequency ranged in the literature from daily to once every other month.
Lamps are often cleaned with the common industrial cleanser Lime-A-Way or a mild acidic solution, such
as hypochloric, phosphoric, muriatic, or citric acid (Nieuwstad et al., 1991). WEM staff (1995) found a
two percent muriatic acid solution to be the most effective and cost efficient.
Two methods are used to clean lp-li lamp arrays, manual wiping or immersion. In smaller plants where the
arrays are relatively small, wiping down each lamp by hand is generally more cost efficient. However, in
larger plants manual cleaning becomes too labor intensive. Immersion cleaning can be accomplished either
in-channel or in an external tank (Mann and Cramer, 1992). Air sparging units are typically used in both
immersion systems and represent a low cost method of extending the cleaning frequency when installed
properly (Blatchley et al., 1996). Air sparging is only effective where the bubbles actually “hit” the
sleeves. In-channel cleaning poses several design difficulties, such as protecting the channels from the
corrosiveness of the cleaning solution, installation of channel drains and isolation gates and valves on both
the upstream and downstream ends of each channel, and ensuring that these isolation gates and valves
remain leak free. An external cleaning tank must be accompanied by a hoist or overhead crane to move the
lamps from the UV reactor to the cleaning tank. Although this method may considerably increase the
capital cost of the system, it is generally the preferred method because it isolates the cleaning solution from
the from the plant effluent.
Ease of cleaning is one of the biggest advantages of the mp-hi and lp-hi lamps. Their increased diameter
allows the lamps to be fitted with an automated wiper system (Trojan Technologies, Inc., 1998). One
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system combines the mechanical wiping of two flexible rubber collars with a chemical cleaning solution
contained within. A hydraulic arm situated in-between two lamps pushes both wipers down the length of
the lamp and back. The process can be completed in-situ and, because the wipers only occupy a small
section of the lamp at any one time, cleaning can progress without any interruption to the operation of the
disinfection unit (Trojan Technologies, Inc., 1998). Automation of the cleaning cycle is programmable and
may be set to run as often as once every hour. Another process, used for an lp-hi lamp system, uses a
pneumatically driven stainless steel or Teflon wiper ring to clean the quartz sleeves. The quartz sleeves are
harder than stainless steel and thus are not scratched. Because of the ease of automatic cleaning, lamp
fouling is not as significant a problem in mp-hi and lp-hi systems.
Environmental Factors
Temperature and pH are generally the environmental factors that play a role in wastewater disinfection.
One of the most heralded advantages of UV disinfection is that, unlike chlorine, it is independent of pH
(Thampi, 1990). However, because UV disinfection is a kinetic process, it is affected by temperature.
Abu-ghararah (1994) investigated the efficiency of UV disinfection of fecal coliform over a temperature
range of 10 – 45 oC. For temperatures below 20 oC, a lower inactivation rate constant was observed.
Between 20 and 40 oC the effect of temperature was negligible.
Temperature is also an issue for the UV lamps since they have an optimum operating temperature.
However, Darby et al. (1993) noted that the air within the fused quartz tube casing, used for UV lamps,
created an insulating effect such that typical ranges in wastewater temperature made little difference in
disinfection performance. As mentioned earlier, the actual dose received by microorganisms in the
wastewater is dependent on the UV transmission of the wastewater itself.
Photoreactivation and Nucleotide Excision Repair
The fact that UV disinfection leaves behind no residual often is thought of as an advantage to using UV.
However, having no residual can potentially have repercussions. It has been well documented that cells
have evolved the ability to repair damage by UV light once the source has been removed. Three
mechanisms of repair have been established, photoreactivation, nucleotide excision repair (NER), and
recombination repair. All three mechanisms are performed by enzymes and, therefore, are affected by
temperature, pH, and ionic strength (Chan and Killick, 1995).
Photoreactivation is known to occur in most cells, except for certain kinds of bacteria and the connective
tissues of placental mammals (Larson and Berenbaum, 1988). The reasons for these exceptions are not yet
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understood. Table 2-3 presents a list of some organisms common to wastewater and their tendency to
photoreactivate.
Table 2-3: Photoreactivation in Wastewater Organisms
(taken from Lindenauer and Darby, 1994)
Positive Response No Observable Response
Escherichia coli
Streptococcus feacalis
Strptomyces
Saccharomyces
Aerobacter
Micrococcus
Erwinia
Proteus
Penicillium
Nuerospora
Fecal Streptococci
Bacteriophage
somatic coliphages
P. Aeruginosa
Clostridium perfringens
Haemophilus influenzae
Diplococcus pnuemoniae
Bacillus subtilis
Micrococcus radiodurans
Photoreactivation occurs in two steps. First, a photoreactivating enzyme, or DNA/RNA photolyase,
attaches to a pyrimidine dimer on the damaged molecule (Voet and Voet, 1995). This step does not require
light. Second, light energy is captured by the complex, the DNA/ RNA is repaired, and the enzyme is
released. This step is called photolysis, because it requires the energy in light to drive the reaction
(Lindenauer and Darby, 1994). The light required for the photolysis step is generally in the wavelength
range of 310 - 490 nm, but differs between organisms. This corresponds to UV-A and the violet-blue
colors, from the visible light range.
Lindenauer and Darby (1994) analyzed correlations between percent photoreactivation and UV
transmittance, suspended solids, turbidity, and initial and surviving organisms. The strongest correlation
was with the number of surviving organisms. This may be an indication that at least a portion of what these
authors are considering photoreactivation is really nothing more than reproduction of the surviving
organisms in the high nutrient, low competition environment of the UV disinfected wastewater.
NER is also called dark repair because, unlike photoreactivation, NER does not require light. In this repair
process, enzymes called UvrABC endonucleases selectively cleave out the damaged portion of DNA in an
ATP-dependant reaction, and then reconstruct the proper molecule using the complementary strand (Voet
and Voet, 1994). NER does not apply to RNA, because RNA is single stranded. The importance of NER
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in the repair of UV damage in humans is apparent due to two rare but severe diseases, Xeroderma
Pigmentosum and Cockayne Syndrome. Both diseases are characterized by hypersensitivity to UV
radiation and are caused by an inherited defective NER process. However, experiments conducted by Chan
and Killick (1995) indicates that dark repair may not play as important of a role in microorganisms.
Recombination repair is a post-replication repair mechanism that occurs in the event that damaged DNA
molecules managed to undergo replication despite the pyrimidine dimer (Voet and Voet, 1995). When this
occurs the replication complex must detach from the DNA at the damaged site and reattach at some point
downstream completing the replication of the remainder of the DNA strand. The unaffected,
complementary DNA strand simultaneously undergoes normal replication. At the end of replication, one
daughter DNA molecule will contain a gap opposite the pyrimidine dimer, while the second daughter
molecule forms a normal DNA duplex. In recombination repair, the gap on the damaged molecule is filled
by exchanging the missing segment of genetic information from the normal sister DNA molecule. This
results in a gap on the normal molecule, which can be filled in readily by reading the complementary
strand. The damaged molecule now has an accurate complementary strand and can be repaired through
photoreactivation or NER. Research on the role of recombination repair in wastewater treatment has not
been published to date. However, since it essentially relies on either of the other two repair mechanisms,
its effects will be included in their measurement.
Safety Concerns with Using UV
Of all the disinfection technologies currently available, UV irradiation is the safest in terms of occupational
hazards (Stover et al., 1986). No reactive chemicals are involved requiring transport or storage issues
(Stover et al., 1986). The high voltage power supplies required may pose some issue, especially with
submerged lamp designs, but compliance with normal electrical safety codes should mitigate hazardous
conditions (TFWD, 1986).
Exposure to dry lamps can produce deleterious health effects. The National Institute of Occupational
Safety and Health (NIOSH) has set limits to occupational exposure to UV light at a wavelength of 254 nm
(Mann and Cramer, 1992). Total exposure doses to UV light during the normal eight-hour work day is
limited to 6 mW-s/cm2. This dose is 10 to 20 times lower than the doses received by the wastewater flora
and requires less than one-sixth of a second of exposure to a dry lp-li lamp to be exceeded (Mann and
Cramer, 1992). Submerging a lamp in water, even if it is just a few inches below the surface, will greatly
reduce the intensity. Thus, UV reactors should be designed to ensure constant water levels to minimize the
risk of exposure.
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Moderate exposure of unprotected skin will cause sunburn or erythema, but continued exposure will cause
the skin to blister and bleed (Mann and Cramer, 1992). Prolonged UV exposure to the eyes may cause
kerato-conjunctivitis. This effect has many common names, such as “welder’s flash,” “arc eye,” and “snow
blindness” and is characterized by an inflammation of the eye (Mann and Cramer, 1992). Although
painful, the damage is not permanent (TFWD, 1986). Besides kerato-conjunctivitis, over-exposure to the
eyes may also cause retinal lesions, cataract formation and a chronic yellowing of the lens (Mann and
Cramer, 1992). Because of the susceptibility of the eyes, protective goggles or fa
Recommended